Filling machine



Jan. 31, 1939. G. J. I-IUNTLE'Y ET AL I 2,145,765 I FILLING MACHINE Filed May 15, 1953 9 Sheets-Sheet l LI /7am Jan. 31,- 1939 G. J. :HUNTLEY ET AL. 2,145,765

FILLING MACHINE Filed May 15, 1935 9 Shets-Sheet 2 G. J. HUNTLEY ET AL Jan. 31, 1939.

FILLING MACHINE Filed May 15, 1933 9 Sheets-Sheet 4 Jan. 31, 1939.

v FILLING MACBINE Fild May 15,1 5 9 sheets-sheets c; J. HUNITLEY ET AL 2,145,765 7 Jan; 31, 1939.

G. J. uNTL'Y ET AL ,7

FILLING MACHINE 9 Sheets-Sheet 6 Filed May 15, 1933- l l T I l I Jan. 31, 1939..

i A99 i G. J. HUNTLEY ET AL FILLING MACHINE Jan. 31', 1939. G. J. HUNTLEY ET AL 2,145,765 FILLING MACHINE Fi'iedMay 15, 1955 9 Sheets-Sheet 8 mm I 422' Q5 nmm 2 $1925 mg llllllllll H I 31, 1939. G, J. HUNTLEY ET AL FILLING MACHINE 9 sheets-sheet 9 gvvum'vtow a o/ a J #02777 n aerdlffm I I i Filed May 15/1933 Patented J n. 31, 1939 v OFFICE- aunas mama mounts George J. Huntley and Robert J. Stewart, Baltimore, Md., assignors to Crown Cork & Beal- Company, Inc, Baltimore, Md., a corporation of New York Application May 15, 1933, Serial No. 671,266

24'Clalms.

The present invention relates to filling maand, abovethe water, a body of gas. The first step or the filling operation is to establish a pressure, generally referred to as counter-pressure, in the bottle, this pressurebeingequal to thepressure of the gas above the water in the water and gas reservoir. -The second operation is to permit the charged water to fiow from the reservoir into the bottle through the filling head. Since the pressure in. the bottle and the pressure in the reservoir are now identical, the water only flows into the bottleby reason 01' the head of 0 water resulting from the elevation of the reservoir above the bottle and as the reservoir is not greatly elevated above the filling head, the flow of water will be comparatively slow. During the fiow of water into the bottle, the pressure in the bottle 1s vented back to the reservoir, but the filling is terminated before the level of the water in the l bottle reaches the mouth of the bottle, and the air and gas confined above the level of the water will be compressed bythe rising water. In order to gradually release this pressure before the mouth of the bottle is opened to the atmosphere, a third step, shifting, is performed, comprising releasing the pressure above bottle through a Ethel; moved out of engagement with the filling The filling heads beneath which the steps. oi. the

filling operation are conducted each usually .com-

prise a valve body carrying a filling nozzle and 40 a valve movable on a valve seat or the valve body. The valve body is provided with a number of passages therethrough extending from the valve seat and communicating with -the filling reservoir for the counter-pressure fiow and the filling and venting fiow. Anotherpassage extends from the valve seat to atmosphere for the snifting fiow. The valve body is also provided with a second series of ports extending from the valve seat to the filling nozzle and corresponding to the abovementionedports. The valve upon the valve body is provided with a number of channels or passages which are adapted to be successively aligned with corresponding passages in the two series of passages of the valve body to M carry out the steps of the filling operation. Fillthe surface of the water in the very small vent.- The bottle is ing trips are provided about the path ofmovement of the filling heads to movethe filling valves to the successive positions which they occupy for the various steps of the filling operation.

Because of the high pressures passing from the valve body and through the valve, the joint between these two parts must be relatively tight, so as to prevent all possibility-of leakage and yet must not be so tight as to cause the valve to stick. In the filling heads now generally used, a tight and close fit between the valve body and valve results in rapid wearing ,of these parts. This requires that the two be adjusted with respect to each other from time to time, but the continual wearbetween the parts causes the timing of the various steps of the filling operation to get out of adjustment with respect to each other. This may result in prolonging the time of some of the steps of the filling operation and shortening the time of other steps and since each 20 filling head must be very accurately adjusted so that each step 01' the operation will be completed in time for the commencement of the next succeeding operation, the operation of the machine becomes unsatisi'actory.- If the filling machine 25 comprises a large number of filling heads, the valve of each of which is worn to a varying degree, filling heads become so greatly out of time that eflicient operation is extremely difiicult.

An important object of our invention is to provide a filling head which is designed to accurately perform each step of the filling operation and in which the valve body and valve are so arranged that they may be held tightly in contact with each other with but a minimum possibility of any wear occurring between the two parts.

Another important object of the invention is to provide an arrangement for causing an individual filling head to be rendered inoperative in the event that no bottle is positioned beneath that filling head, thereby preventing the waste of filling water as well as unnecessary wetting'of the machine.

Numerous arrangements have been provided in prior art machines for preventing the waste of filling water when no bottle is positioned beneath a filling head. In some of these arrangements, the entire machine has been stopped upon the failure to position a bottle beneath the filling head. By other constructions, the filling head valve has been rendered inoperative for the filling step, but no provision has been made to prevent the operation of the valve to other steps in the filling cycle. In still other machines, separate devices have been provided at each 01' the in accordance with the English or filling trips to successively prevent the operation or each of the trips to actuate the-filling valve.

In the arrangement embodied in our machine, the trips which cooperate with the filling head valve to successively move the latter to the various steps of the filling cycle are spaced about the machine in the usual manner, but means are provided to render the counter-pressure trip inoperative with respect to a filling head if no bottle is positioned beneath that head. Also, the counter-pressure trip, filling trip and filling valve are so designed with respect to each other that if the counter-pressure trip is rendered inoperative and fails to actuate the valve to counterpressure position, the valve will subsequently fail to make contact with the filling trip. It will be noted that by this. construction, wherein the counter-pressure trip is rendered inoperative, counter-pressure gas as well as filling water will be conserved.

Our mechanism to render a. filling head inoperative when no bottle is positioned beneath the head is so designed that it will properly coact with each succeeding filling head to operate or fail to operate the latter, according to whether the head is or is not aligned with a bottle to be filled.

Another object of the present invention is to provide a filling nozzle which 'is so designed that each bottle of a run of bottles will be filled to exactly the same height.

Members of the bottling trade make particular efiorts to have each bottle in a case of bottles filled to the same height since there can then be no question in the mind of the retailer .or the ultimate consumer as to short-filling of any bottle in the case.

To meet the demand for uniform height of filling, the filling heads of our invention are each provided with a filling nozzle so designed that the filling of a bottle will be automatically stopped when the level of the liquid in the bottle rises to a predetermined point. When the level of the liquid reaches this point, the venting of air from the bottle will be discontinued, thereby preventing more liquid from flowing into the bottle. The filling nozzle includes extremely simple means to permit the height of the air vent outlets with respect to the filling nozzle to be very readily adjusted without requiring any adjustment of .the filling nozzle itself, and the adjustment of the height of filling may therefore be readily accomplished.

The filling system used with .the present machine is generally similar to the well known English filling system, but the various novel arrangements of the structure discussed above whereby the filling is conducted and other. ar-

rangementswhieh will be apparent fromthe specification and drawings, eliminate all of the disadvantages of the English filling system, an important object of the present invention being to provide a filling machine which will operate high-low? filling system but which is so substantially improved over machines constructed to operate inaccordance with that system as to develop the full advantages of the system.

The filling nozzle preferably used with the present machine includes a bottle centering bell which is slidable upon the filling nozzle. so that the mouth of the bottle will be properly centered about the nozzle before the nozzle moves into the bottles. During the fillingoperation, the center ing bell and the filling head proper are sealed together with an air-tight joint and the bottle is snifted through the centering bell and the filling head.

Another important object of our invention is to provide a filling head and connections from the head to the filling reservoir which will make for more efllcient filling.

In the operation of filling heads, a considerable amount of water flows from the filled bottle back toward the filling reservoir through the venting passage during the filling step of the filling operation. When the flow of waterto the bottle is stopped and the filling valve is moved from filling position to shifting position, the water which has flowed upwardly through the vent passage will be held in the vent passage. When the bottle which has been filled is moved from a filling head and an empty bottle positioned beneath the same head for filling, the water which has been in the vent passage will fiow down into the second bottle during the step of establishing counter-pressure in this bottle, since the passage which is used as a vent passage during the filling step is also used as a pressure flow passage during the counter-pressure establishing step. The fiow of a considerable amount of water into the bottle ahead of the counter-pressure gas is distinctly undesirable since the pressure of the counterpressure gas causes the water to be projected against the walls of the bottle with some force and induces disturbance of the gas with which the water is charged." I

Our filling head is so constructed and arranged with respect to the filling reservoir that a very short passage is provided between the filling head and the reservoir and this passage is of extremely small diameter. By this arrangement, only a very small quantity of water can ever flow upwardly through the vent passage.

Another object of our invention is to so constructthe filling mechanism that the charged water will be kept cool and at proper temperature to hold the carbon-dioxide gas with which the. filling water is charged in the filling water reservoir to the filling heads in a body of insulating material, thereby preventing any increase in the temperature of the filling water.

Another object of our invention is to provide a machine which may be operated at relatively high speeds over 'a long period of time and the parts of which are -so arranged that the entire machine may be readily adjusted for various alzes of bottles or to compensate for any wear which may occur.

It will be understood that the apparatus of the present invention may be used to fill containers of any type with fluids of various natures.

Numerous other objects and advantages of the machine will be apparent from the following specification and drawings, in which:

Figure l is a horizontal sectional view 'of the machine taken on the line |l of Figure 2;

Figure 2 is a vertical sectional view taken on the line 2-2 of Figure '1;

Figure 3 is a vertical sectional view through one of thebottle supporting platforms of the filling mechanism, showing the platform in the position it occupies when adjacent the worktable;

Figure 4 is a plan view of one oi! the bottle supporting platformsg- .Figure 5 is a horizontal line 5-5 of-Flgure 10;

Figure 6 is a detail elevation showing the ars ectional view on the -rangement and operation of the counter-pressure andfilling trips, parts of the mechanism being shown in vertical section;

Figure 7 is a horizontal sectional view of the mechanism illustrated in Figure 6, but with the filling heads removed;

Figure 8 is a detail horizontal sectionalfview on the line 88 of Figure 6;

Figure 9 is a vertical sectional view of the structure shown in Figure 7 andincluding a filling head;

Figure 10 is a sectional view through the counter-pressure trip controlling valve;

Figure 11 is a view of one of the filling heads, showing thepassages and ports of the valve body and valve, the filling nozzle being shown in vertical section. In this view, the filling valve is shown rotated just slightly past true snifting position in order-to make the arrangement of the alignedv passages more apparent;

Figure 12 is a horizontal sectional view on a' the filling valve arm in snifting position. The two other operating positions of the valve arm are shown in dotted line; v

Figure 16 is a central vertical sectional view of the structure shown in Figure 15; Figure 17 is a vertical sectional view through the filling head and valve in counter-pressure position, the view being diagrammaticin that it shows the passages and ports used in the counterpressure step in the same vertical plane;

Figure 18 is a view of the same type as Figure 17, but showing the venting ports used in filling in the same vertical plane;

Figure 19, is a View also of the same type as Figure 1'7, but showing the passages used for filling during the filling operation and in the same vertical plane;

Figure 20 is a view of the same type as the three preceding figures, but with thepassagesused during-snifting shown in the same vertical plane.

Our filling machine comprises a syruping mechanism 5|, a filling mechanism 52 and a crowning mechanism, not shown, the syruping mechanism and crowning mechanism being supported upon hollow rotatable shafts 54 and 55, respectively, extending up through the worktable 55, while the filling mechanism is rotatably supported adjacent the rear edgeof the worktable, upon a vertical column 51 extending upwardly from the base 58 of the machine.

As ;is best shown in Figure 1, a straight line endless conveyor 59 having the surface of its upper run fiush with the level of the worktable 55 feeds the bottles into the machine at 50, the bottles being removed from the conveyor 59 by an infeed spider 5| fixed to a stub shaft 52 journalled in the worktable. The bottles are moved about the spider 5| in a clockwise direction to a rotary table 53 and spider 54 included in the syruping mechanism and are removed from the syruping table and spider by a central or transfer spider 55, which is fixed to a vertical shaft 55 journalled in the worktable and base. The transfer spider 55 moves the bottles about its left-hand portion to position them upon bottle supporting platforms 5'! spaced about the filling mechanism 52. The rotating filling mechanism moves the bottles thereabout in a clockwise direction (Fig. 1) and returns the bottles, filled, to the right-hand portion of the transfer spider 55. The bottles are removed from the filling mechanism and are moved about the right hand side of the transfer spider 55 to a rotary table 58 and spider 59 included in and forming part of the crowning mechanism not shown, but which is preferably of the rotary type provided with vertically reciprocating crowning heads as shown in our application for Filling machine, filed-April 19, 1938, a division of the present application. During the movement of the bottles about the crowning mechanism spider 59 in a counter-clockwise direction. they are crowned and are removed from the latter spider by an outfeed spiderlll secured to a stub shaft II 'journalled in the worktable 55. The outfeed spider 10 moves the bottles in a clockwise direction upon the worktable to the right-hand end of the straight line conveyor 59, which moves the bottles from the machine.

Worktable 55 is carried by a supporting structure comprising-side walls and a front wall I4, all extending upwardly from the base 58 as shown in Figure 2.

The syruping mechanism 5|, filling mechanism 52 and the crowning mechanism mounted on the shaft 55 above the crowning spider 53 are rotated in synchronism by suitable driving mechanism described in our said divisional application filed April 19, 1938, this mechanism also effecting moveso that the reservoir may rotate relatively to the" pipe and may be adjusted vertically with respect thereto.

Bottles are guided in their movement from the straight line conveyor 59 to the infeed spider 5| by means ofa guide member I55 positioned on the worktable 55 at the outer side of the straight line conveyor and also by a guiding device generally; indicated by the numeral I55 positioned on the-inner side, of the straight line conveyor and extending opposite the infeed spider 5| throughout the path of movement of the bottles about the spider. The outer guide member I55 is curved at its inner end, as shown at I51, to direct the bottles inwardly toward the spider and upon the worktable, this end of the guide being reduced in vertical cross-section, so that it may project.

between the upper and lower spaced flanges of the spider 5|. The flanges of the spider are provided with""pockets I50 to engage the bottles fed thereto byrthe straight line conveyor. In order to permit the machine to operate upon bottles of various sizes, the outer guide member I55 is mounted for adjustment, having a flange I5I adjustable on the worktable.

The-inner guide member I55 includes a base plate I52 adjustably secured to the worktable 55 by means of bolts extending through slots in the plate and threaded into the surface of the worktable, as shown. The plate I52 has a vertical flange I53 thereon extending along the inner side upon the syruping table 63 and in the pockets whenever a jam occurs.

7 plates .table and extending the angled plate I64 being normally held in the position shown in Fig. 1 by means of a coil spring I66 surrounding a stud secured to the plate I64 adjacent its pivot point, the inner end of the spring bearing against the rear surface of the angled plate and its outer end bearing upon theinner surface of a bracket I61 fixed with respect to the base plate I62. through thebracket I61 and may be provided with lock nuts to normally hold the angled plate I 64 in proper position. The free end of the angled plate I64 overlaps the adjacent end'of the upstanding flange I63 of the base plate I62, so that the angled plate will be held'in proper inward position with respect to the spider 6| and straight line conveyor 59. The inner guiding element I56 also includes a curved guide plate I68 surrounding the inner portion of the path of travel of the bottles about the spider, plate I68 including a horizontal angled portion resting upon the worktable 56 and held thereto by bolts extending through slots' in the horizontal portion.

Means is provided in connection with the inner guiding element I56 for preventing jamming of the receptacles being fed from the straight-line conveyor 59 to the spider 6|, these means being so arranged that the machine will be stopped This means is described in our above-mentioned divisional application filed April 19, 1938. As shown in Figure 2, the syrup enters the syrup reservoir 2I6 of the machine by a pipe line 2 leading from a storage tank.

Syrup flows to the syruping heads 2I3 through lines 2I6 and thence to each bottle moving with the syruping spider 64 by the mechanism described in detail in our divisional application Serial No. 6,720, Filling head, filed February 15, 1935.

The bottles will be held properly positioned 66a of the syruping spider by a central guide element 26I which is provided with downwardly extending walls 262 of suflicient height to prevent thebottles from falling over or moving from the rotating syruping table. As'is shown in Figure 1, the central guide member 26I includes an extension 263 which projects between the spaced plates of the infeed spider 6I so that the bottles will be properly moved from the latter spider by the syruping spider. Theinner endof the guide member 26I extends between the spaced 264 of the transfer spider 65 to properly guidethe bottles from the syruping spider to the transfer spider. As is indicated in Figure 1, the spaced plates 264 of the spider65 are spaced above'and below the spider 64 of the syruping mechanism so that the two spiders may interengage abouta bottle.

The transfer spider 65 is formed and secured to its shaft 66 in the manner described in our above-mentioned divisional application filed April 19, 1938, to permit it to be removed so that spiders of various sizes may be'used on the shaft 66. A similar arrangement would be used with the other spiders of the machine.

A guide member shown in Figure 1 is provided to properly direct the movement of bottles about the left hand side of the transfer spider 615 from the syruping mechanism to a bottle supporting platform 61 of the filling mechanism. This guiding mechanism comprises a plate 265 secured to the worktable 56 by bolts threaded into the workthrough slots in the plate to permit adjustment of the latter forrunsof The stud is slidable 1 form 61 spring 3 I 6 and guide the reciprocating movement bottles of various sizes. A curved upstanding guide element 266 extends across the surface of the table 63 of the syruping mechanism, this element being bifurcated so that it extends above and below the syruping spider 64. A movable guide plate 261 is pivoted to the guide element 266. The curved and movable guide plate 261 is normally held in position to properly guide the course of bottles from the pockets 266 of the transfer spider 65 to the bottle supporting platforms 61 by a coil spring 266 about a bolt pivoted to the rear surface of the movable plate 261, one end of the spring bearing against the movable plate and the other end contacting with an upstanding bracket on the horizontal and fixed plate 265. Lock nuts may be provided upon the bolt to limitinward movement of the movable plate.

The filling mechanism bottle platforms is provided with a threaded portion 363 at its lower end which threadedly engages a bore 364 in a slide block 365. The slide block is movable between slideways 366 extending outwardly from a skirt 361 secured to the lower outer ed'ge'of the table I62. A roller 368 is rotatably mounted upon a stud 366 threaded in a horizontal bore in the block 365. A coil spring 3I6 is mounted about the rod362, the upper end of the coil spring bearing upon a collar 3 welded to the upper end of the rod bottle platform rotation by means of a pin 3I2 extending from the bottle platform into a cutout portion in the collar 3I I. upon a collar 3I3 mounted upon the rod 362 and provided with a shoulder which engages a shoulder 3! on the outer surface of the skirt 361 of the table I62. The table I62 is provided with an upstanding boss 3I5 through which the rod 362 exs tends in a vertical bore 3I6 provided through the boss. Telescoping tubes 3" and 3I8, respectively, are secured to the underside of the bottle platand the lower collar 3I3 to enclose the of the bottle platform'61. A bushing may be provided in the bore 3I6 as shown in Figure 3. During the greater part of the rotation of the filling mechanism, the bottle platforms 61 are in the upper position the expansion of the spring 3I6. A platform is only in the lowered position shown in Figure 3 when the platform is adjacent the worktable 56, at which time, as illustratedin this figure, the roller 366 on a bottle supporting platform will contact with a cam shoulder 3I9 secured to the supports of the worktable so that the surface of the .bottle supporting with the level of the worktable 56 to permit bottles to be moved from the worktable to the platform 'and vice versaby the transfer spider 65. Each bottle platform 61 is provided with a bottle engaging member 326, which is removably supp rted upon an upstanding shoulder 32I on the inner side of the bottle support as described The lower end of the spring 3I6 bears shown in Figure 9 due to 362 beneath the surface of the 61. The rod 362 is held against platform 61 will be flush in our above-mentioned divisional application filed April 19, 1938.

The filling trips bottle supporting platforml carried by the tating filling mechanism. approaches the work-v table 55 from theright (Figure 1), the roller 305 included in the bottle supporting platform structure will contact with the fixed cam shoulder '3l5 projecting downwardly from the inner edge of the worktable. Contact of the roller 305 .with

the cam causes the bottle supporting platform to be drawn downwardly to the position shown in Figure 3 wherein the upper surface of the bottle supporting platform is fiush with the upper surface of the worktable. If a filled bottle is on the platform, the transfer spider 55 will remove that bottle as hereinafter described and will position a syruped bottle upon the platform and the bottle will be moved in a counterclockwise direction toward a counter-pressure trip 352 supported above the worktable and hereinafter referred to in detail. The cam M9 is of such configuration that Broadly considered; .each filling head comprises a body portion 402 provided with a filling valve 403 to control the flow of'liquid, air and'gas there- '1 through in a manner hereinafter explained. Each filling head is also provided with a filling nozzle 404 having a centering bell 455 slidably mounted thereon. The filling valve 403- is provided with a valve lever 405 including a downwardly extending arm 40'! and an upwardly extending arrn 405. The downwardly extending arm 40! includes an outwardly projecting ofiset portion 400.

- prise the counter-pressure trip 35! and-a filling thebottlesthrough the filling mechanism. a I 75 The expansion of the spring 3i0of a bottle platform 51 permitted by the movement of the roller 308' from beneath the cam 3| 9 will move' the bottle supporting platform 51 upwardly so that the bottle carried thereby will be moved upwardly, the outer peripheryof the mouth of the bottle contacting with the inner surface of the centering bell405 provided on the filling head. The inclined walls of the centering bell will cause the mouth of the bottle to be centered, as it is moved upwardly, so that the mouth of the bottle will move up about the filling nozzle 4.04 on the filling head. The spring 3l0 has sufficient length and: strength to hold the bottle pressed against the interior of the centeringbell to provide a tight seal between the mouth the interior of the bell.

The value lever 405 of each filling head is adapted to be moved to various positions duringthe rotation of the filling mechanism inorder to successively move the valve 403 to counterpres'sure-position, filling position, and shifting position. The movement ofv the valves to these positions is accomplished by means of trips spaced about the path of travel of the filling mechanism. As is best shown in Figure 1, these trips comtrip 353,-both supportedv on the worktable 55 adjacent the infeed end of'the path of travel of the filling mechanism. The s ifting trip 354 is also supported on the worktable 55 but is positioned adjacent the outfeed end of the path of travel of The detailed construction of the counter-pres of the bottle and 5 sure and filling trips and the manner of the ope ation of the filling valves is best shown in Figures 6, 7 and '9. Referring to Figure 9, itwill be ob- 4 from a, collar 350, which collar is mounted on the other arm 352 of the bracket .359 in the same manner that the counter-pressure trip cylinder 355 is mounted in arm 355. By having the two trips rotatably mounted upon the arms of the bracket 359, they are enabled to move out of thepath of any jammed or improperly positioned filling valve lever 405, thereby preventing damage to the trip arms as well as to the valve arms.

As shown in Figures-6 and 8, the bracket 359 is vertically adjustable upon a supporting post 353 fixed to the table 55. The post 353 has a screw shaft 354 therein which is mounted for rotation in the upper end of the post, the upper end of the shaft being provided with an operating handle, as shown.eA nut 355 is threaded upon the post 354, which nut is supported by diametrically oppo- "Bsite pins 355 havingtheir inner ends projecting into sockets in the side wall of the nut to hold the nut against rotation. The outer ends of the pins 355 are held in key plates 35'' secured by bolts 355 to the opposite inner surfaces of the vertical bore through the bracket 359 by bolts 353. The keys: 351 move in diametrically opposite vertical slots 310 formed in the walls-of the post 353. It is obvious that by this arrangement,

rotation of the threaded shaft 354 will cause the bracket 355 to move vertically. 'The bracket 359 and the trips carried thereby can thus be moved vertically to be properly positioned for any vertical adjustment of the filling heads and filling valves.

The snifting trip 354 is mounted on a bracket 354;: (Figure 1)' in the same manner that the filling trip at: is mounted on bracket :59, and the snifting trip 'is therefore free to rotate out of the path of a jammed filling valve lever. The bracket, I 354a is vertically slidable upon a post 3541; so that its position may be vertically adjusted to accord with changes in the elevation of the filling valve levers. Post 35417 is secured to the worktable 55. The bracket 354a moves on a vertically extending key on post 3541: to prevent variance of its angular position with respect to the post.

As has been stated above, during rotation of the filling mechanism, the filling valve lever 405 and the filling valve 403 of each filling head will be successively moved to difi'erent positions by the filling trips 352,353 and 354, thereby filling the bottles carried on the bottle platforms. The structure and operation of the filling heads and valves will be, subsequently described.

, of that filling head includes a release control lever an pivoted at m to a brtcket :m which is secured to the supporting structureof the worktable 55. I The release control lever 3' is'normally held V passage of .the rollers 308 beneath the same in a 314 is secured on the supporting structure of the,

thepositionshown in Flguresfi and 9 by the manner-hereinafter described. A valve casing worktable 56 immediately above the bracket 313 andtwo valve stems 315 and 316 respectively projectfrom the lower side of the valve casing toward the release control lever 31I. Release control lever 31| carries an upwardly projecting adjustable ta'ppet, 315a which contacts with the lower end of a valve, stem 315 and a second tappet 316a is held in contact with the lower end of a valve stem 316 by a coil spring 31Gb.

As is best shown in Figures 9 and '10, the valve stems 315 and 31.6 are slidable in the valve casing 314, stem'316v carrying a two-faced disk valve 319 at its upper end within a valve chamber 380, which valve is normally held seated against the lower seat 381 by a spring 382 positioned between the 'upper face of the valve and the lower surface of the upper wall of the valve chamber. Valve stem 315 has a relief valve 384 secured to its upchamber is merely a dead end in the pressure circuit. The air flowing into the valve chamber 380 moves past the valve 319 and out of a lateral port 388 and'through a pipe 389 to the cylinder 355 in whicha plunger 390 carrying the counter-pressure trip 352 is mounted. The pressure thus acting against the plunger 390 holds the plunger to the left (Fig. 9) against the action of a coil spring 390a, therebyholding the counter-pressure trip 352 outwardly and in operative position.

,During the initial movement of a filling head 400 and the bottle, platform beneath the same away from the worktable 56, i. e., in the direction platform 61 3|0 will move the platfor of the'arrows on Figures 6 and '1, respectively, the roller 308 of the platform moves out of engagement with the cam shoulder 3|9 beneath the worktable. raised by its spring 3|0 in the manner already described. If a bottle has been positioned on the by the transfer spider 65, the spring 61 upwardly until the centering bell 405 of the h ad has been carried upwardly by the mouthof the bottle, and into contact with the lower portion of the filling head 400; proper. Since further expansion of thespring 3l-0 is now prevented, the roller 308'on the slide block 305 connected to the-bottle platform 61 by the rod 302 will be positioned in a predetermined horizontal plane. With the roller 308 positioned in this plane, the filling head 400 and its bottle platform 61 will continue to move in the direction of the arrows of Figures 6 and 7 and to a position corresponding to that indicated at H in both Figures 6 and '1. At'this' point, the roller 308 of the platform will move beneath the release control lever 31!. Because the platform 61 carries the bottle, the roller 308 will merely have :a brush-- ing contact with the release control lever 3H and will'not disturb the position of this lever. The position of the counter-pressure trip 352 will therefore not be effected and during movement-of the roller 308 beneath release control lever Thispermits the platform 61 to be the projection 409 on the lower arm 401 of the filling valve lever moved in a counterclockwise direction (Figure 6) to counterpressure position. Y

The roller 308 will continue in brushing contact with the release control lever 31! for a short interval of time after the valve lever 406 has been moved to counter-pressure position, but will move out of contact with lever 311 before the valve arm 401 'comes in contact with the filling" trip 353. When the projection 409 on the valve arm 401 strikes the filling trip 353, it will be swung still further in a counter-clockwise direction (Fi ure 6) so that-the filling head will begin to fill the bottle in a manner subsequently to be described.

When, for any reason, the transfer spider 65 fails to position a bottle upon a bottle supporting platform 61, the movement of the cam roller 308 of that platform clear of the cam shoulder 3|9 will permit the bottle supporting platform to move slightly upwardly past the posltionit occupies when a bottle is carried by the platform, due

406 will contact with counter-. pressure trip 352 and the filling valve'403 will be to the fact that the spring 3l0,of the platform I 'may now expand to maximum extent. The

height to which a platform 61 will move when no bottle is present upon the platformis indicated at position E in Figure 6. With the platform at this higher position, the roller 308 of the platform will be' sufiiciently elevated to press against the under side of the'release control lever 31l to swing the latter lever upwardly on its pivot 312. The upward swinging movement of the release control lever 31l will cause the tappets 315a and 316a to respectively. move the valve stems 315 and 316 upwardly from the position shown in Figures'9 and 10.

The upward movement of the .valve stem 316 will cause the disk valve 319 carried thereby to move upwardly to seat against an upper seat 39l in the valve chamber 380. Movement of the valve against seat 39l will cut off, at this point, the flow of air through the pipe 381 from the tank I18. The simultaneous upward movement of the valve stem 315 will move the release valve 384 carried thereby from its seat 392, thereby permitting the pressure which exists in the valve 'casing 314, line 389 and in cylinder 355 behind of the counter-pressure trip 352 to the right, will move it out of the path of the lateral extension 409 on the lower arm 401 of the filling head valve lever arm 406 and the filling valve 4.03 will thus move past the counter-pressure trip 352 without being actuated to counter-pressure position.

The height and position of the filling trip 353 which the valve arm 406 normally next strikes is such that when the.valve arm is not moved from theposition it occupies at position B in Figure 6, it will pass beneath and clear of the filling trip 353 without being actuated to filling position, passing the filling trip 353 at the position indicated at position E in Figure 6. It results from the above, that the filling valve 403 passes filling trip 353 in the same position it occupies when it passed the-transfer spider 65, at which time, as

hereinafter explained, it was insnifting position. Hence, since the valve is in snifting position, it

will not be actuated bythe snifting trip 354 and therefore the filling head 400 moves entirely about the filling mechanism without being actuated.

It will be noted, from the above, that the filling heads 400 are individually controlled to prevent their filling operation when no bottle is positioned beneath a filling head. In other words, a waste of filling water is entirely prevented without the necessity of stopping the entire machine or in any way affecting any part of the machine other than the individualfilling head.

As shown in Figure 6', the portion of the release control lever 31l with which rollers 308 contact is of such length that a roller 308' which is in upward position will contact with the lever for a sufiicient length of time to cause the counter-pressure trip 352 to remain in inoperative position for the length of time necessary to permit the valve arm 403 of the filling head (beneath which there is no bottle), to entirely clear the trip 352. Furthermore-the contacting portion of lever 31l'is long enough to cause one roller 308 to always be in contact therewith, and with one roller coming into contact just as another roller passes out of contact. This renders the lever immediately sensitive to the position of each incoming roller and since one roller 308 will always be beneath the lever, the lever will be held at either normal or slightly raised position. Because of this, no other stop means need be pro.- vided to prevent the lever 3" from dropping entirely downto vertical position.

The pivot 312 of the lever 31! has an-eccentrio portion which seats-in the bore therefor in the bracket 313. By this arrangement,-the normal position of the lever 31l may be varied to obtain the desired operation and timing. The eccentric portion may be held properly locked to hold the pivot 312 at the desired elevation by means of a set screw 304. The springs 386 and 382 which normally hold the valve stems 315 and 316 in the position shown in Figure 10, likewise serve to hold the lever 31! in normal downward position. The spring 31Gb between the head of the tappet 316a and the upper surface of the lever 31l will permit the lever 3' to move very slightly upwardly without affecting the seating of the valve 319 since the latter will momentarily be held seated by its spring 302. ,Such a compensating arrangement is necessary due to the fact that bottles of the same capacity may vary slightly in height. The slight upward movement of thelever' 31I referred to may move the release valve stem 315 upwardly without affecting the position of the counter-pressure trip 352, or the tappet 315a may be adjusted to such a position that it will not unseat the release valve 384 by a slight upward movement of the lever MI.

The disk valve type of filling head The disk valve type of filling head used in our seat or depression 310. A leather washer 4|3 and a rubber washer 4 are positioned' in the valve seat 4l0 between the valve seat face 4| 5 and the face 4 l6 of the valve. The rubber washer M4 is placed in contact with the valve seat face 415 and the leather washer H3 is positioned between the face MB of the valve and the rubber washer, the smooth or finished face of the leather washer being positioned in contact with the valve face 6.

The valve 403 is held in close sealing contact with the leather washer 3 by means of a nut 411 threaded on the outer end of the stud 4| l. 5

The central portion 8 of stud 4 is unthreaded to permit the valve 403 to readily turn thereon and an anti-friction device M9 is interposed between the nut 4| 1 and the outer face of the valve 403 to permit the valve to turn freely with 10 respect to the nut. This anti-frictiondevice comprises a collar 420 having an inwardly extending flange 42!. A metal washer 422 anda rubber washer. 423 are positioned on the outer side of the'fiange 42l, the metal washer bearing against the nut H1. The inner end of the collar 420 is provided with an inwardly'projecting shoulder 424 which holds a washer 425 in position at that end of the collar. Anti-friction bearings 420 are positioned between the washer 425 and the inner surface of the flange MI inorder that the washer 425 may be freely rotatable.

It will be obvious that the anti-friction device 4l9 will permit the nut 4l1-to be tightened. to

the extent necessary to maintain a tight seal between the disk valve 403 and the valve body 402, without exerting any appreciable retarding eifect upon the rotation of the valve 403.

Since the finished or smooth face of the leather washer H3 is in contact with the face 416 of the valve disk, contact between the two will exert a minimum retarding effect against rotation of the valve disk and the rubber washer 1H4 behind the leather washer will prevent the escape or flow of gas or liquid behind and between the washers and faces of the valve body and valve disk. The washers are provided with ports aligned with ports in the valve body 402 and small collars 421 seated in the ports in the valve bodyc-extend into the ports in the washers, thereby prevent- 40 ing rotation of the washers with respect to the valve body.

As has been heretofore stated, the valve disk 403 is provided with a valve lever 406.

The lower surface of the valve body 402 is provided with a downwardly projecting portion 428 having a central bore 429 therein. A collar 430 is held tightly in engagement with the downwardly extending portion 420 by means ofa flanged nut 43l threaded upon the downwardly extending portion, 420. A gasket 432 is positioned between the collar 430 and the downwardly extending portion 328. A filling tube 433 ext-ends from the enlarged lower end of the bore 429 of the extended portion 428 and through the collar 430, the upper end of the tube being provided with an annular flange 434 which seats upon the upper surface of the collar 430. A preferably conical head 435 isthreaded upon the lower end of the tube 433, this head being provided with radial apertures 436. A sleeve 431 is positioned upon the filling tube 433, the sleeve and tube forming the filling nozzle 404'. The. lower end of the sleeve 431 rests upon the conical head 435 while the upper end of the-sleeve extends up intothe enlarged lower end of the bore 430 through the collar 430. A packing ring 439 seated in a groove in the bore 430 surrounds the upper end of the. sleeve 431.

The centering bell 405 is slidably mounted upon the filling nozzle 404, and is provided with a V compressible packing ring 440 against which the. mouth of the bottle is adapted to bepressed'.=

- As will hereinafter be more fully explained, the centering bell 405 is adapted to be moved up :tending from the passage wardly upon the filling nozzle 404 by upward movement of the bottle to be filled, and, by this movement; the upper surface of the centering bell will be brought into contact with a packing ring 441 provided upon the lower end of the collar 430 and projecting past the lower end of the collar to provide a tight seal between the centering bell and collar.

The valve body 402 is adapted to be connected to the filling reservoir I41 by pipes 442 and 443 (Fig. 1). Referring to Figure 2, it will be observed that-in the filling reservoir I41 the pipe 443 opens into the lower portion of the reservoir and beneath a body of charged water while the pipe 442 extends above the level 'of the charged water and opens to a body of gas which is maintained above the charged water in a. manner hereinafter set forth. 'A pipe 442 and a pipe 443 double-ended or substantially U-shaped passages which are adapted to bridge corresponding pascages in the valve body 402 so that the filling nozzle 404 will be properly connected, seriatim, to the valve body 402 to carry out the various steps of the filling cycle by reason of the turning'of the valve disc 403.

The arrangement of the passages in the valve body 402 and valve disc 403 will be more clearly understood from a description of the various;

steps of the filling cycle take in connection with Figures 17 to 20 inclusive- However, Figure 11 shows these passages in front elevation and with the valve disc 403 turned slightly in a clockwise.

direction with respect to the valve body 402 from the position which it would occupy during the snifting step of the filling cycle. The valve disc is turned in the manner noted in order that the arrangement of the various passages may be more clearly observed.

When the filling mechanism is rotated to bring a filling head 400 toa position where the downwardly extending valve arm 401 of the valve lever 406 thereof will contact with the counter-pressure trip 352 (Figural), the valve 403 will be turned, in a counter-clockwise direction (Figures 11 and 15) from 'snifting position (the position it occupies when a bottle in placed beneath the head and which is shown in solid lines in Figure 15) to counter-pressure position (shown in dotted lines in Figure 15). The counter-pressure passages in the valve body and valve disc will thenbe aligned as diagrammatically illustrated in Figure 17. Referring to Figure 1'1, the gas flow pipe 442 connected to the rear surface of the valve body 402 is open to two passages 450 and 45! extending through the valve body 402. 'A'

passage 452 which extends through the valve disc 403 parallel with the inner surface 6 of the valve disc, is provided with short axial passages 453 and 454 which are respectively aligned with the inner ends of the passages 450 and 451 .in the valve body. A third axial passage 455 exshort axial passage 456 in the valve body 402 which leads to a. vertical passage 451 in the valve is aligned, as shown in a counter-pressure and body. The passage 451 Figures 11 and 1'1, with I of the water therein.

452 is aligned with a vent passage 458 which extends. diagonally through the collar 430, the lower end of the passage 458 opening into a passage 459 between the filling tube 433 and the sleeve 431 which surrounds the filling tube. The passage 459 is provided by flattening one outer surface of the filling tube 433, this flattened portion extending sufliciently far up upon the tube 433 to terminate above the upper end of the sleeve 431 so that it may communicate withthe passage 458. The lower end of the flattened passage 459 terminates beneath small apertures 460 in the lower end of the sleeve 431 (Figure 11) When the valve disc is turned to align the various passages in the manner described above, gas will flow from the upper portion of filling reservoir I41 through pipe 442 to pass-ages 4,50 and 451 in the valve body, through passages 453 and 454 to passage 452 and from passage 452 through passages 456, 451, 458 to passage 456 in the filling nozzle. and thence through one of the apertures 460 to the interior of the bottle, thereby establishing the same pressure in the bottle as exists in the filling reservoir I41 above the level It will be noted that a check valve 46l is provided at the enlarged inner end of the valve body passage 450 but when gas is flowing in the manner described, this ball valve will be loose and unseated in the passage 450 so that gas may flow through this passage. 1

As the fillingmechanism continues to rotate, the downwardly extending valve arm- 401 of filling valve disc 403 will strike the filling trip 353 so that the valve lever will move in a counterclockwise direction to the filling position illustrated in dotted lines in Figure 15. This will move the valve disc to a position wherein the passage 452 in the valve disc and certain of the axial passages aligned therewith will-be aligned with passages in the valve body. as is shown in Figure 18, to permit air and the gas which has been placed in the bottle to be vented from the bottle while another passage 462 will be connected. (as diagrammatically shown in Figure 19) with passages in the valve body to permit charged, I

water to flow from the filling reservoir I41 to the bottle.

Referring to Figure 18, it will be observed that the axial passage 454 in the valve will be aligned with the axial passage 450'in the valve body while a fourth short passage 463 in the valve and extending from the passage 452 to the inner face of the valve disc will now be aligned with the passage 456 in the valve body which leads to the passage 459v in the filling nozzle. Referring to Figure 19,. the second passage 462 in the valve disc 'will be aligned with a generally axial passage 464 in the valve body 402. The passage 464 communicates with an offset passage 465 having an enlarged portion 466 through a plug valve 461 seated in a'vertical' bore 468 in the valve body.

The plug valve 461 includes a central vertical bore 469 and two transverse ports 410 and 4' communicating, respectively, with the passage 464 and the passage 465. The water pipe 443 from the filling reservoir I41 is connected to the enlarged portion 466 of the passage 465 and when the 'valve 461 is in the position shown. charged water may' fiow through passage 465 and valve 461'to' the passage 464.

' The valve 461 is provided with a stem 412 an a knurled handle 413 by means of which. the valve may be rotated to adjust its position. Packing 414 is provided about the stem 412 and a sleeve 415 is threaded in the bore 468' to hold i the packing properly clamped. Passage 46 2 is provided. with a short axial passage 411 which,

' with the parts in the, position shown in Figure 19,

is aligned with the water pass-age 464 and a second short passage 418 sage 462 valve'body to the interior of the filling tube 433.

By the arrangement described above, charged water will fiow into the enlarged portion 466 of the passage 465, through valve 461 to passage 464, and thence through passages 411, 462 and 468 in the disc valve to the water passage 419 and tube 433. From the tube 433, the water will pass through the apertures 436 in the conical head 435 of the filling nozzle 404. Due to the fact'that the pressure in the bottle has already been established, by the counter-pressure step previously described, at the same pressure as the pressure of the body of gas above thewater in the filling reservoir I41, the water from the reservoir 141 will only flow to the bottle by reason or the slight elevation of the tank I41 above the bottle. The head of this water never exceeds two pounds; and the water will therefore only flow at a very slow rate. This will result in a gradual filling of the bottle without agitation 'oithe syrup or water. During the time that the water is fiowinginto the bottle, the air and gas in the bottle will be vented 'throughthe passages shown in Figure 18 the air and gas leaving the bottle through the small apertures 460 in the sleeve 431 and passing up through the passage 459 to the passage 458 and then through passage by passages 463,

451, passage 456 and through the disc valve 403 452 and 454 to the axial passage body 402 and then through the the upper portion oi. the filling 450 in the valve pipe 442 back to Y reservoir I41.

Water will continue to flow into the bottle so long as the gas-and air in thebottle is provided with a means of escape but when the bottle. is filled with water. up to the ports 460 in the sleeve 431, the air and 'gasremaining in the bottle abovethe level of the water will have no pathof escape and will be compressed to some extent by reason of the fact that the water. will rise very slightly above these ports and will then begin to fiow through the ports 460 and through the fiattened passage 459 in the circuit previously followed by the venting air and gas.' Water may flow through this venting passage until the level of the water in the pipe 442 reaches the level of the water in the tank- I41, but the water valve 461 on the valvebody 402 and the speed and timing of the entire machine are so adjusted as to cause "the bottle through the vent tube are reflected in the small 442 through which the water may flow upwardly is as straight as possible.- v

The advantages of the above arrangement whereby a minimum amount of water may fiow amount of'water which'may 'be discharged into a fresh bottle wh'. n the filling head is again operated to. counter-pressure position.

The arrangement described above whereby the extends from the pasin the disc valve to an angled water passage 419 extending downwardly through the bottle may only be filled up to the vent ports 460 in the sleeve431 is of distinct importance in the bottling trade since it insuresthat every bottle will be filled to a certain distance measured from the top of the bottle. It is very desirable to the bottling trade to have. bottles filled exactly to the same height from thetop oi the bottle and, by our arrangement, this can be accomplished regardless of variances in the capacity of bottles of similarly rated sizes.

The tube 431 of the filling nozzle is provided with a second pair of ports 460' which, as shown in Figure 11, are below the ports 460 on the tube and are circumferentially spaced from the latter ports so that both sets of ports cannot be in alignment with the flattened passage 459. The apertures 460 are ordinarily used for filling 8 ounce bottles, but when bottles of a larger diameter are to be filled, for example, quart bottles,

the sleeve 431 may be rotated upon the tube 433 to move the ports 460 out-of alignment with the flattened passage 459 and to the lower ports 460' in alignment with the lower end 01' the passage. Bottles of larger sizes than the 8 ounce size are, according to standard practices, filled to a greater distance from the than the 8 ounce bottles and'the lower ports 460' will therefore serve for suchbottles. It will be understood that additional ports similar to 460 and 460. may be spaced along and about the sleeve 431 to fill bottles of other sizes to the proper height.

In the event that a bottle should be broken during the filling step, described above, the pres:

top 01' the bottle in the enlarged portion 466 ofpassage 465 to seat against the opening in passage 466,thereby preventing the undue escape oi! water If any gas should fiow outward by gas line 442 it will also be'cut oil? by reason of the fact that the ball valve 461 in the enlarged end of the passage 450 through which gas and air has previously been vented will move to close this passage. It may be stated here that should a bottle break during the counter-pressure step illustrated in Figure 17, gas will be tree to flow to atmosphere through the passage "I and the passages connecting the latter to the bottle. However, the counter-pressurestep is'oi such short duration that no appreciable amount 01' gas will-be wasted.

Continued rotation 01' the filling head will cause the upwardly extending valve lever 408 on the valve disc to contact with the shifting trip 354 so that the valve disc will be rotated in a clockwise direction to the position shown in full lines in Figure 11 to place the shifting ports of the valve body and-valve disc in alignment. By this movement, the water passage through the tube 433 and the flattened passage! between the tube 433 and sleeve 431 will be entirely closed. Sniitingis accomplished through very small keri's or cut-outs 435 (Figures 11 and 12) circumferentially spaced about the wall of the bore through the centering bell 405, the inner faces of the cut-outs being closedby the sleeve 431. The kerfs or cut-outs 435 open into the space in the bottle between the filling nozzle 404 and the inner .wall 01 the mouth oi the bottle, the mouth of the bottle of course being pressed tightlyagainst the packing ring in the centering bell.

The upper ends or the kerts 405 open into an annular chamber 433 in the lower end of the collar 430, this chamber being sealed to the atthe chamber 486, a passage 481 extends upwardly I through the collar 430 and is aligned with a pass sage 488 at one side of tbe water passage 418 (Figure 11). Referringto Figure 20, it will be noted that the passage 488 includes a portion 489- extending axially of the valve body 402 and which is now in alignment with one arm of a U- shaped passage 49!! in the'valve disc. The other arm ofthe U-shapedpassa'ge 490 is in alignment with an axial passage 49I in the valve body which has an upwardly extending portion opening into avalve chamber 492. From the valve chamber 492, a diagonal passage 493 extends to the exterior of the valve body.

Snifting will occur through the passages described above, the rapidity of the snlfting being governed by a needle valve 494 threaded in the upper portion of the valve chamber 492 and provided with a knurled head 485; The needle valve 494 may be locked in adjustedposition by a lock vnut 495. I

It will be observed that the filling head structure described above insuresthat the water will fiow quietly into the bottle; will only rise to a predetermined height in the bottle; and that each step of the filling cycle will be conducted inproper timed relation to the other steps. The

structure described above will also prevent waste of filling water and gas by reason of the breaking of a bottle.

The fillma reservoir lated covering 50! within'an outer casing 502 encloses the reservoir. Water tubes 443 extend from the lower portion of the reservoir I41 to each of the filling heads 400 and counter-pressure or venttubes 442 extend through the 'bottom wall of the reservoir to a point near the upper portion of the reservoir, one of the tubes 442 also being provided for each of. the filling heads 400. Only one set of these tubes is illustrated in Figure 2. As is shown in Figure 2,- the tubes 442 and 443 are enclosed within a body of insulating material designated by the numeral 503 and positioned between the supporting skirt I46a of the reservoir and a cover 504.

As is shown in Figure 2, and as has been described, the column-51 upon which the filling The filling reservoir of our preferred construc tlon is described in detail in'ourabove-mentioned' divisional application filed April'l9, 1938, the structure being such that a proper level of water will be maintained in the reservoir, with a substantially uniform body of gas at uniform pressure above the water.

After the bottles have been shifted, the continued rotation of the filling mechanism will move them back toward the transfer spider 85. As the bottle supporting platforms 6] move along worktable 56, the roller 308 in each platform will move into engagement with the cam track 3I9, moving the bottle platform downwardly to the level of the worktable, as is shown in Figures 2 and 3; The timing ofthe rotation of the filling mechanism and the transfer spider is such that a bottle will be presented to each pocket 260 of the transfer spider as the pocket moves across a bottle supporting platform 6L In order to insure that the bottles are removed from the platforms 61, a guide member 525 is positioned upon the worktable 56 beneath the transfer spider and extends out over the path of the platforms I51 and beneath the bottle'engaglng members 320. As is best shown in Figure 1, the guide member 525 has the right hand face thereof curved to define the path of travel of the bottles from the platforms and into the pockets of the transfer spider. In order to hold the bottles in the transfer spider and guide their movement thereabout, a guide element 526 is adjustably fixed upon the surface of the worktable 56 adjacent the right hand sideof the path of travel of the transfer spider. The bottles are moved by the transfer spider about the right hand side thereof and onto the table '68 of the crowning mechanism 53 into the pockets 521 of the crowning spider 69.

' As is described in our above-mentioned divisional application filed April 19, 1938, the table 68- of the crowning mechanism 53 and the spider 69 thereof are of exactly the same construction as the table and spider of the syruping mechanism 5|. The crowner comprises four crowning heads equidistantly spaced about the crowner supporting structure which is keyed to the rotating hollow shaft 55, the heads being verticallyv ,slidable in the supporting structure, with one head in alignment with each crowner spider pocket 521, so that as bottles move about the spider they will be crownedbefore being moved to the outfeed spider 10, which moves them between guides 588 and 590*and places them on the outfeed end of the straight-line conveyor 60 as described in our above-mentioned divisional application filed April 19, 1938,

The operation of the various mechanisms disclosed herein has been specifically set forth in connection with the structures of such mechanisms. All features disclosed but not claimed are claimed in our divisional application for Filling head, Serial No. 6,720, filed February 15, 1935, or our divisional application for Filling machine, filed April 19, 1938.

It will be understood that the invention is not limited to the, details ofconstruction shown in the drawings and that the examples of the use of the machine and mechanisms which have been given do not include all of the uses of which they are capable and that the phraseology employed in the specification is for the purpose of description and not of limitation.

We claim:

l. The combination in a filling machine havin a reservoir for liquid and gas, of a filling head including a valve body, the valve body having a series of ports therethrough for liquid and gas communicating with the reservoir and leading to.

adapted, upon seriatim movements of the valve,

to bridge corresponding ports of the two series of ports in the valve body-to permit gas to flow from the reservoir to a container, to subsequently permit liquid'to flow from the reservoir to the container and to simultaneously vent the container, and the valve body having a port extending from the filling nozzle to said face thereof and a corresponding port extending from said face to atmosphere, said lastv named ports being adapted to be placed in communication by ,a port in the valve upon further movement of ports leading from said face of the valve body to the filling nozzle, a disk valve rotatably mounted upon said face of the valve body and having ports therein adapted, upon seriatim movements of the valve, to bridge corresponding ports of the two series of ports in the valve body to permit gas to flow from the reservoir to a container, to subsequently' permit liquid to flow from the reservoir to the container and simultaneously vent the container, and the valve body having a port extending from the filling nozzle to said face thereof and a corresponding port extending from. said face to atmosphere, said lastenamed ports being adapted to be placed in communication by a port in the valve upon further movement of the valve to permit the container to be shifted.

3. The combination in a filling machine hav-' ing a reservoir for liquid and gas, of a filling head including a valve body, the valve body having a series of ports therethrough for liquid and gas communicating with the reservoir and leading to one face of the valve bod a filling nozzle on the filling head andsadapted to be positioned in a container, the valve body having a second series of ports leading from said face of the valve body to the filling nozzle, a valve fmounted'upon saidface of the valve bodyand having ports therein adapted, upon seriatim movements of the valve, to bridge corresponding ports of the two series of ports in the valve body to permit gas to fiow from the reservoir to ,a container, to subsequently permit liquid to fiow from the reservoir to the container and to simultaneously vent the container, and'the valve body having aport extending from the filling nozzle to said face thereof and a corresponding port extending from said face to atmosphere, said last-named ports being adapted to be placed' in communicar' tion by a port in the'valve upon further'movement of the valve to permit the container to be s ifted, one of the valve body ports through which liquid flows being provided with a valve to control the rate of fiow of the'liquid.

4. The combination in a filling machine including a reservoir for liquid and gas, of a fillling head including a valve body, the valve body having a series of ports therethrough for liquid and gas communicating with the reservoir and leading to one face of the valve body, a filling nozzle on the filling tube and sleeve, a valve on said face. of

the filling head having ports therein adapted, uponseriatim movements of the valve to bridge corresponding ports of the two series of ports in the valve body'to permit counterpressure flow from the reservoir to the-container through said filling head having por sleeve.to subsequently permit liquid to fiow from the reservoir to the container through said filling nozzle and to permit simultaneous vent flow from the container to the reservoir through the sleeve, the valve body having a port extending from the upper portion of the filling nozzle to said face of the valve body and a corresponding port extending from saidface to atmosphere, said'last named ports beingadapted to be placed in communication by a port in the valve upon further movement of the valve to permit snifting fiow.

5. The combination in a filling machine having a reservoir for liquid and gas, of a filling head including a valve body, the valve bodyhaving a series of ports therethrough for liquid and gas communicating with the reservoir and leading to one face of the valve body, a filling nozzle on the filling head, said filling nozzle including a filling tube and a sleeve thereabout, a second series ofports in the valve body extending from said face thereof and respectively communicating with said filling tube and sleeve, a valve on said face of the filling head having ports therein adapted, upon seriatim movements of the valve, to bridge corresponding ports of the two series of ports in the valve body to permit counter-pressure flow from the reservoir through said sleeve, to subsequently permit liquid to fiow from the reservoir through said filling nozzle and a simultaneous vent flow through the sleeve and the ports aligned therewith, and said valve body having a port extending from'sald face to the upper portion of the filling nozzle exteriorly of said sleeve and a corresponding port extending from said face to atmosphere, said last named portsbeing adapted to be placed in communication by a port in the valve upon further movement of the valve to permit snifting fiow.

6. A filling head including a filling nozzle, said therethrough communicating with a filling re I 'rvoir and extending to a valve seat in the filling head, a second series of ports extending from said valve seat to the filling nozzle, a valve on said valve seat to place corresponding ports of said series of ports in communication seriatim to permit counter-pressure, liquid and liquid venting and snifting fiow through the ports, and valves in the passages through which liquid and snifting fiow occurs to regulate the idegreelof such fiow.

7. The combination in a filling head of a valve body and avalve movably mounted upon-the valve body, the valve body and valve being respectively provided with corresponding passages adapted'tobe placed in alignment upcn move: ment of the valve, a packing between the valve and valve body, said packing being provided with l ports aligned with the valve body passages and comprising a sealing disc of non-porous and resilient material adjacent the valve body and a disc of porous material adjacent the valve.

8. The combination in a filling head, of a valve body and a valve movably mounted upon the valve body, the valve body and valve being respectively provided with corresponding passages adapted to be placed in alignment upon movebody and a valve movablyTmounted upon the 

